Abstract
There is no consensus about how terrestrial biodiversity was assembled through deep time, and in particular whether it has risen exponentially over the Phanerozoic. Using a database of 60 859 fossil occurrences, we show that the spatial extent of the worldwide terrestrial tetrapod fossil record itself expands exponentially through the Phanerozoic. Changes in spatial sampling explain up to 67% of the change in known fossil species counts, and these changes are decoupled from variation in habitable land area that existed through time. Spatial sampling therefore represents a real and profound sampling bias that cannot be explained as redundancy. To address this bias, we estimate terrestrial tetrapod diversity for palaeogeographical regions of approximately equal size. We find that regional-scale diversity was constrained over timespans of tens to hundreds of millions of years, and similar patterns are recovered for major subgroups, such as dinosaurs, mammals and squamates. Although the Cretaceous/Palaeogene mass extinction catalysed an abrupt two- to three-fold increase in regional diversity 66 million years ago, no further increases occurred, and recent levels of regional diversity do not exceed those of the Palaeogene. These results parallel those recovered in analyses of local community-level richness. Taken together, our findings strongly contradict past studies that suggested unbounded diversity increases at local and regional scales over the last 100 million years.
Highlights
Life on land today is spectacularly diverse, accounting for 75–85% of all species [1,2]
The palaeogeographical spread (=spatial extent) of the terrestrial fossil record itself grows exponentially through the Phanerozoic and is decoupled from the actual terrestrial area that existed through time
The palaeogeographical spread (=spatial extent) of the terrestrial fossil record grows exponentially through the Phanerozoic and is decoupled from the actual terrestrial area that existed through time
Summary
Life on land today is spectacularly diverse, accounting for 75–85% of all species [1,2]. To control for the pervasive spatial sampling biases affecting the terrestrial fossil record, we estimated diversity and other key variables for approximately sized palaeogeographical regions, which we defined by drawing spatial subsamples of adjacent fossil localities (on a per-interval basis). Spatial variables include the counts of occupied equal-area grid cells (i.e. cells yielding fossil occurrences) spanning a range of sizes (100, 200, 500, 1000 and 5000 km spacings, calculated using the R package dggridR [29]); our primary measure of palaeogeographical spread, MST length (= the minimum total length of all the segments connecting spatial points in a region [30]; see Close et al [11] for justification); the distance of the longest branch in each MST (used to identify spatial regions with widely separated clusters of localities). Clicking on a data point plots the underlying data on a palaeomap and displays tables of the underlying occurrence data in that palaeogeographical region
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